DE19882705C2 - Adaptive split band modulator - Google Patents

Description

Field of the Invention

This invention relates generally to power amplifiers and particularly on high power broadband power amplifiers Efficiency. In particular, the invention relates to a method ren according to the preamble of claim 1 and a adaptive split band modulator according to the preamble of Claim 7.

Background of the Invention

Various devices are for amplifying signals available. For amplifier applications that require amplification and Transmission of modulated signals involve a The main focus is on amplifier efficiency. In addition, since many applications have a wide range require a major consideration on the ability to efficiently produce a high fidelity reproduction a broadband signal.  

Communication devices that often transmit broadband signals are an example of an application in which this quality ten are in demand. A low disturbance allows the Communication devices to communicate more reliably and high efficiency allows the devices to work longer with a single battery.

Broadband communication signals usually have correspondingly wide modulation bandwidths. That is, if a signal occupies a large RF bandwidth, the changes Envelope of the signal within this bandwidth quickly. An amplifier that efficiently outputs a signal of this type amplified, preferably has a large RF bandwidth and a wide range of modulation.  

One method of achieving increased efficiency is to use single-shell amplifiers Envelope Elimination and Restoration (= EER)) to be used. EER is a technique by which highly efficient but nonlinear high frequency (RF) power amplifiers with other, highly efficient Amplifiers for producing highly efficient linear amplifier systems com can be binary. The signal to be amplified is split into two ways: one Amplitude path and a phase path. The detected envelope becomes efficient in the Amplitude path through an S-Class or other highly efficient power amplifier ker amplifies who works more with the bandwidth of the RF envelope than the RF bandwidth tet. The phase modulated carrier in the phase path is then amplitude modulated by the amplified envelope signal, which he an amplified reproduction of the input signal testifies.

In EER-type amplifiers, the envelope signal, which is the modulation bandwidth occupied, amplified in the amplitude path. Use conventional EER type amplifiers the S-Class modulators to reinforce the modulation bandwidth in the envelopes that of the input signal is included. Unfortunately, S-Class modulators are in the Bandwidth at the switching frequency at which they operate is limited, and with the increase in Switching frequency, the S-Class modulators become less efficient. This practical edge condition sets a maximum modulation bandwidth for any given ver greater efficiency is achievable.  

DE 30 17 521 C2 discloses a two-channel sound power amplifier where a signal is in a high frequency part and split a low frequency part. By doing high frequency branch of the amplifier circuit is next to the High pass filter circuit a constant current amplifier scarf tion provided. However, no measures are suggested gene to increase the efficiency of the amplifier circuit.

DE 44 39 826 A1 relates to a method and a device device for amplifying a signal. It describes how an input signal successively in a driver stage and one Power amplifier is amplified and the harmonic components at the output the output stage are filtered out. The problem of ef efficient amplification of a broadband RF signal, which ei ne does not show a large modulation bandwidth addressed.

The invention is therefore based on the object Method and an adaptive split band To provide modulator that effi A broadband RF signal that amplifies a large mo shows bandwidth.

This task is accomplished with the features of the independent claims che solved.

Advantageous embodiments of the invention are shown in FIGS pending claims specified.

Brief description of the drawings

The invention is particularly in the dependent claims exposed. However, other features of the invention obvious, and the invention is best understood by referring to the following detailed description in conjunction with the accompanying drawings, of which:  

Fig. 1 shows a diagram of an amplifier according to a preferred embodiment of the present invention;

Figure 2 shows an illustration of an adaptive split band modulator according to a preferred embodiment of the present invention;

Fig. 3 shows an amplifier according to an alternative embodiment of the present invention;

Fig. 4 is a diagram showing a communication apparatus according to a preferred embodiment of the present invention; and

Fig. 5 shows a flow diagram for a method of amplifying a signal in accordance with a preferred embodiment of the present invention.

Detailed description of the drawings

In general, the present invention helps to solve the problems identified above, by providing an amplifier that efficiently matches broadband signals accordingly high modulation bandwidths.

Fig. 1 shows an illustration of an amplifier according to a preferred embodiment of the present invention. The EER-type amplifier 10 includes a power divider 210 , an envelope detector 220 , an adaptive split band modulator 270 , a time delay element 230 , a limiter 240 and a power amplifier 260 . The EER type amplifier 10 receives an RF input in the power divider 210 . The power divider 210 divides the RF input signal into a phase path that supplies the envelope detector 220 and a phase path that supplies the time delay element 230 .

The phase path of the EER type amplifier 10 includes the time delay element 230 , the limiter 240 and the power amplifier 260 . The time delay element 230 , which generates a delay equal to that introduced by the adaptive split band modulator 270 in the amplitude path, receives an output from the power divider 210 . Limiter 240 receives the time delayed signal output from time delay element 230 and amplitude limits the signal. The limiter 240 may be omitted, or may perform a soft limiter, but the limiter 240 preferably performs a hard limiter so that the limiter 240 output contains the phase information with little or no amplitude information. After the limitation, with the amplitude information removed, the resulting signal is the phase modulated carrier. The phase modulated carrier output from the limiter 240 is input to the power amplifier 260 . Power amplifier 260 is any amplifier stage that can be modulated, and is preferably a field effect transistor (FET) amplifier. The drain of the FET is conventionally connected to a DC power source; however, as discussed below, in a preferred embodiment, described here as an example, the drain of the FET is operated with a signal resulting in an amplitude modulated output signal.

In a preferred embodiment, the time delay element 230 is used in the phase path since it is desirable to recombine the signals from the amplitude path and the phase path after each has been subjected to substantially equal delays. The absolute delay of the time delay element 230 is such that the total delay in the phase path is substantially equal to the total delay in the amplitude path. The time delay element 230 is shown as the first element in the phase path; however, the actual placement of the time delay element 230 within the phase path is not a limitation of the present invention. Since the function of the time delay element 230 is to compensate for the delay in the phase path and in the amplitude path, the actual position of the time delay element 230 in the phase path is not important.

Alternative embodiments of the present invention substantially match the delay in the two ways using circuitry other than that which uses only the time delay element 230 . In a first alternative embodiment, different delay lines, one in the phase path and one in the amplitude path, are used. In this case, the absolute delay of any delay line is less important, and the differential delay between the two delay lines is used to match the delays in the two paths. In another alternative embodiment, a differential delay line, such as a surface acoustic wave (SAW) with one input and multiple outputs, is used as a combination of the power divider 210 and the delay element 230 . In this alternative embodiment, as in the first alternative embodiment, the differential delay is used to match the delay in the two ways.

The amplitude path of the EER-type amplifier 10 includes the envelope detector 220 and the adaptive split band modulator 270 . The envelope detector 220 detects the envelope of the RF input signal and outputs an envelope signal that represents the amplitude information contained in the original RF input signal. The envelope detector 220 is preferably a diode detector; however, other types of detectors such as a synchronous detector based on a double balanced mixer could be used.

The adaptive split band modulator 270 amplifies the envelope signal output from the envelope detector 220 and drives the drain bias of the power amplifier 260 . The adaptive split band modulator 270 amplifies the envelope signal to a level comparable to the desired output. The output of the adaptive split band modulator 270 is the power supply for the power amplifier 260, and the resulting remodulation of the phase-modulated carrier restores the envelope, producing an enhanced reproduction of the input signal.

The amplifier EERtype of FIG. 1 varies the drain bias of the Leistungsver stärkers 260 in such a manner that the operation is maintained near saturation and therefore in a high area efficiency. Because the high efficiency power amplifier 260 consumes most of the power consumed in the EER type amplifier 10 , the entire circuit is remarkably more efficient than conventional amplifiers.

Fig. 2 shows a diagram of an adaptive split band modulator in accordance with a preferred embodiment of the present invention. Split-band modulators combine at least two amplifiers, each of which amplifies a different bandwidth. In a preferred embodiment, the split band modulator contains two amplifiers, a first amplifier for amplifying the low-frequency components and a second amplifier for amplifying the high-frequency components. The first amplifier is one that amplifies low frequency components efficiently, and the second amplifier is one that amplifies signals over the bandwidth of the first amplifier. The split-band modulator is advantageous because it is a broadband amplifier than the first, efficient amplifier and it is also more efficient than the second, broadband amplifier.

In a preferred embodiment, as exemplified in FIG. 2, the division band modulator combines an S-class modulator as the first amplifier and a B-class amplifier as the second amplifier in order to obtain a larger bandwidth, than is possible with an S-Class amplifier alone. The low-frequency components of the envelope are efficiently amplified by the S-Class modulator. The high-frequency components are amplified by the B-Class amplifier and added to the output of the S-Class modulator. Because the low frequency components make up most of the power in the envelope, the split band modulator is noticeably more efficient than a simple B-class amplifier. The adaptive split band modulator 270 includes a high pass filter 710 , a peak detector 730 , a voltage regulator 740 , a B class amplifier 750 , a high pass filter 770 , a low pass filter 720 , an S class modulator 760 and a low pass filter 780 .

The adaptive split band modulator 270 is arranged such that the low frequency components of an input signal are amplified separately from the high frequency components of the input signal. In a preferred embodiment, the low frequency components are separated from the high frequency components using the low pass filter 720 . The low-frequency components that are output from the low-pass filter 720 are amplified by the S-class modulator 760 .

The S-Class 760 modulator efficiently amplifies the low frequency components, generates amplified low frequency components that are then input to the 780 low pass filter. At the output of the low pass filter 780 there is a delayed and amplified version of the low frequency components of the input signal.

The amplification of the low-frequency components, as has just been described, is carried out very efficiently by the 760 S-Class modulator. The S-Class modulator 760 efficiently amplifies the signal by pulse width modulating its input, producing a pulse width modulated signal, and then filtering the pulse width modulated signal to produce the output. Since the S-class modulator 760 includes a pulse width modulator that works as a switching device, it works more efficiently than a linear amplifier such as an A-class or B-class amplifier as long as the switching frequency is not excessively high. As previously mentioned, the maximum bandwidth that can be efficiently amplified by the S-Class 760 modulator is a function of, among other things, the switching frequency. In practical applications, the switching frequency of the S-Class modulator is limited, since above a certain switching frequency of the S-Class modulator it becomes less efficient and the profits from the use of an S-Class modulator are reduced. As a result of the high efficiency of the S-Class modulator 760 within a given bandwidth, it is desirable to amplify as much of the input signal as possible in the low-frequency path of the adaptive split-band modulator 270 .

The high frequency components of the input signal are separated from the low frequency components of the input signal using the high pass filter 710 . The high-pass filter 710 outputs the high-frequency components, which are then amplified by the B-class amplifier 750 . The output of the B-class amplifier 750 drives the high-pass filter 770 and the resulting signal is combined with the low-frequency components that are generated in the low-pass filter 780 .

The filters on the outputs of the S-class modulator 760 and the B-class amplifier 750 have a finite delay associated with them. The delays are such that the low frequency components and the high frequency components are recombined with similar delays so that the result is a reproduction of high fidelity of the input. In addition, the adaptive split band modulator 270 has a delay associated with its operation as a whole. When the adaptive split band modulator 270 is used in an EER type amplifier to amplify the envelope of a signal, the delay of the adaptive split band modulator 270 is compensated for by time delay means in the EER type amplifier. For example, in the embodiment of the EER type amplifier of FIG. 1, the delay of the adaptive split band modulator 270 is compensated for by the time delay element 230 .

B-Class amplifiers are generally not as efficient as S-Class modulators. It is therefore desirable to reduce the use of the B-Class 750 amplifier as much as possible. In addition, when the B-class amplifier 750 is used, it is desirable to keep the operation of the B-class amplifier 750 in its most efficient operating range, thereby maintaining a high average efficiency. At this end, the peak detector 730 detects the amplitude of the high-frequency components and drives the voltage regulator 740 .

In response to the amplitude of the high-frequency components, the voltage regulator 740 generates the supply voltage for the B-Class amplifier 750 . By keeping the supply voltage of the B-Class amplifier 750 close to the peak amplitude of the high-frequency components it amplifies, the B-Class amplifier 750 is kept in a more efficient operating range. The peak detector 730 and the voltage regulator 740 adaptively follow the amplitude of the high-frequency components and supply the B-class power amplifier 750 with power accordingly. If there are few or no high frequency components, the B-Class amplifier 750 receives little or no supply voltage and the power is not unnecessarily wasted by biasing the B-Class amplifier 750 .

The efficiency of the adaptive split band modulator 270 depends on the distribution of the signal power amplified by each amplifier as well as the peak to average ratio of the part amplified by the B-Class amplifier 750 , from. The two parameters are heavily dependent on the signal that is being amplified. When the adaptive split band modulator 270 is used to amplify the envelopes in an EER-type amplifier, the signal that must be amplified by the B-Class amplifier 750 consists of the high-frequency components of the envelopes. In general, the peak-to-average ratio of this signal is as large as or greater than the envelope itself. Both the amount of power and the peak-to-average ratio of this signal depend on the type of RF signal and the part of the signal Envelope that can be reinforced by the S-Class modulator.

B-Class amplifiers are most efficient when the peak amplitude of the signal matches that maximum output of the amplifier matches. Conventional split tape Modulators use fixed supply voltages. Because the supply voltage must be large enough to receive the largest possible signal, works in one conventional distribution band modulator of the B-class amplifier at less than the ma maximum possible efficiency for all other signals.

The adaptive split band modulator 270 efficiently amplifies a bandwidth larger than that which can be efficiently amplified by the S-Class modulator 760 alone. In addition, the adaptive split band modulator 270 amplifies this wide bandwidth more efficiently than a conventional split band modulator. The adaptive components, including the peak detector 730 and the voltage regulator 740 , work to increase the efficiency of the radio frequency path beyond that of a conventional split band modulator.

The foregoing description of the adaptive split band modulator 270 has resulted in the use of an S-class modulator to amplify the low frequency components and a B-class amplifier to amplify the high frequency components. In addition, the supply voltage of the B-class amplifier is modified adaptively to increase the efficiency of the B-class amplifier. The S-class modulator and the B-class amplifier are meant by way of example and are not the only types of amplifiers that can advantageously be used while the present invention is being carried out. In alternative embodiments, amplifier types other than the S class can be used to amplify the low frequency components and amplifier types other than the B class can be used to amplify the high frequency components.

This advantageous circuit arrangement, which has a highly efficient gain delivering a wider bandwidth provides many advantages. An advantage includes the ability to Amplify a wider modulation bandwidth, which enables the efficient amplification of the larger RF bandwidths is made possible in an amplifier of the EER type.

Fig. 3 shows an amplifier according to an alternative embodiment of the vorlie invention. In Fig. 3, an intermediate frequency (IF) signal is shown as the input signal of the amplifier 20 of the EER type. The IF signal is input into the power divider 210 . The power divider 210 operates to split the input signal in the amplitudes and the phase path. The amplitude path supplies the scaling amplifier 215 and the phase path supplies the time delay element.

The amplitude path of the EER-type amplifier 20 includes the scaling amplifier 21 S, the envelope detector 220, and the adaptive split band modulator 270 . With the exception of the scaling amplifier 215 , these elements correspond to the elements from FIG. 1, which have the same names and the same reference numerals. In addition, the adaptive split band modulator 270 corresponds to the adaptive split band modulator 270 of FIG. 1, which was discussed in detail previously in connection with FIG. 2.

The scaling amplifier 215 receives the peak detection signal from the power amplifier 210 and also receives a feedback signal from the feedback network 225 . The feedback network 225 in turn receives its input from the coupler 265 , which samples the envelope of the RF output. This feedback path, which includes coupler 265 , feedback network 225, and scaling amplifier 215 , helps reduce any non-linearities caused by adaptive split band modulator 270 and power amplifier 260 .

Coupler 265 is used to sample the output signal for feedback. Of course, any means of sampling the output could be used in place of coupler 265 , and the present invention is still practiced. The coupler 265 takes a scan of the RF envelope and feeds it back in amplitude via the feedback network 225 . This feedback arrangement provides the well-known benefits of feedback to an amplifier that operates at a very high frequency without the need to feed back the very high frequency signals. The bandwidth requirements of the loop are dictated by the bandwidth of the envelope and not by the RF bandwidth, so that the advantages of the feedback can also be realized with the increase in the frequency of the RF signals.

Feedback network 225 is analog or digital, but is preferably analog. Feedback network 225 includes circuits known in the art, such as attenuators. The scaling amplifier 215 is one of many different types of amplifiers, for example an operational amplifier.

In the case of the disturbance caused by the power amplifier 260 , the feedback path helps to reduce the amplitude disturbance resulting from a non-linear amplitude transfer characteristic between the drain bias input and the output of the power amplifier 260 . In the case of the interference caused by the adaptive split band modulator 270 , the feedback path helps reduce interference caused by the transition area between the low pass filters 720 and 780 ( FIG. 2) and the high pass filters 710 and 770 ( Fig. 2) are caused.

Significant improvements in the intermediate modulation products can be achieved with the feedback of the envelopes in the EER-type amplifier, as shown in FIG. 3. The method and apparatus of the present invention, as set forth in FIG. 3, improve the intermodulation performance of the EER-type amplifier enough to allow full power operation and still meet the strict adjacent channel power requirements.

The phase path of the EER-type amplifier 20 includes the time delay element 230 , the limiter 240 , the frequency converter 250 and the power amplifier 260 . The time delay element 230 , limiter 240 and power amplifier 260 correspond to the elements shown in FIG. 1 with the same names and the same reference numerals. In contrast to the embodiment shown in FIG. 1, the alternative embodiment of FIG. 3 includes frequency converter 250 in the phase path. The frequency converter 250 receives the signal in the phase path and also receives a local oscillator (LO) signal. Frequency converter 250 converts the frequency of the carrier signal to its final RF frequency using circuitry well known in the art, such as a mixer. The resulting signal is then used to drive the power amplifier 260 , which operates at the final RF frequency.

Due to the operation of frequency converter 250 , the amplifier of FIG. 3 receives a signal at a frequency that is different from the final RF frequency. Figure 3 shows IF signal input to amplifier 20 of the EER type. In addition, those skilled in the art will understand that a baseband signal could also be used. Therefore, in the alternative embodiment shown by way of example in FIG. 3, the input signal may be at any frequency that is different from the RF frequency.

With this circuit arrangement, in which the frequency converter 250 is an integral part of the amplifier, the amplifier is integrated even more closely with the device which receives the amplifier more. The tighter integration results in smaller, less power consuming devices that are easier to manufacture.

The feedback path and frequency conversion as shown in Figure 3 need not be implemented together. That is, the amplifier of FIG. 3 could be implemented with a frequency conversion but without the feedback, and conversely the amplifier of FIG. 3 could be implemented with the feedback and without the frequency conversion.

Fig. 4 shows an illustration of a communication device according to a preferred embodiment of the present invention. The communication device 300 includes an amplifier 320 and an antenna 310 . The amplifier 320 may include any of the amplifiers of the present invention, such as the EER type amplifier 10 ( FIG. 1), the adaptive split band modulator 270 ( FIG. 2), or the EER type amplifier 20 ( Fig. 3) included. Communication device 300 may be one of many different devices that are capable of communicating. Examples include, but are not limited to, subscriber units in a communication system, radio receivers, transmitters and transceivers, one-way and two-way pagers, and cellular phones.

Fig. 5 shows a flow chart for a method for amplifying a signal according to a preferred embodiment of the present invention. In step 510 , an input signal is split into two components: a low frequency component and a high frequency component. A signal can be split into low frequency and high frequency components using a variety of means. One possibility is the use of passive filters. With the separation of the low-frequency component from the high-frequency component, the two components can be modified without affecting the other. In particular, they can be reinforced using different means.

After the input signal is divided into two separate components, the low-frequency component is amplified in step 520 using an S-class modulator. The S-Class modulator amplifies the signal by generating a pulse width modulated signal with a duty cycle that is proportional to the amplitude of the low-frequency component of the input signal. The pulse width modulated signal is then low pass filtered to produce an amplified reproduction of the input signal.

Then, in step 530, the peak of the high frequency component is detected. The peak of the high frequency component is regulated in step 540 and the resulting regulated peak signal is used to drive a B-class amplifier in step 550 .

Then in step 560 the B class amplifier is used to amplify the high frequency components. After the low frequency components in the S class modulator have been amplified and the high frequency components in the B class modulator have been amplified, the resulting amplified components are combined in step 570 to produce an amplified reproduction of the original signal ,

In summary, the method and apparatus of the present invention as they have been described above, provide a versatile way to achieve efficient Amplification of a signal with a large RF bandwidth and a correspondingly large one Modulation bandwidth. Embodiments of an EER-type amplifier having an ad aptive split band modulator have been described. The adaptive Split band modulator efficiently amplifies and allows a broadband envelope EER-type amplifier, a broadband RF signal that has a correspondingly broadband Modulation bandwidth has to be amplified efficiently.

The foregoing description of the specific embodiments will fully disclose the general nature of the invention that others, by applying current knowledge, will readily modify and / or adapt such specific embodiments for various applications without departing from the basic concept, and therefore are Adaptations and modifications are intended to be included within the meaning and scope of the equivalents of the disclosed embodiments. For example, peak detector 730 and voltage regulator 740 could be combined, or power amplifier 260 could be composed of multiple stages.

It is understood that the sentence choice and the terminology used here for the Purpose of description and not limitation. Accordingly, the inventor intended to include all such alternatives, modifications, equivalents and variations to fall within the spirit and broad scope of the appended claims.

Claims (10)

1. A method for amplifying an input signal, the method comprising the steps of:
Splitting the input signal into a low-frequency component and a high-frequency component;
Amplifying the low frequency component with a first amplifier to produce an amplified low frequency component;
Amplifying the high frequency component with a second amplifier to produce an amplified high frequency component; and
Combining the amplified low-frequency component and the amplified high-frequency component, characterized in that a supply voltage of the second amplifier is set as a function of an amplitude of the high-frequency component. 2. The method of claim 1, wherein the step of setting a supply voltage comprises the steps of:
Detecting the peak of the high frequency component to generate a peak detection signal;
Regulating the peak detection signal to produce a regulated signal; and
Setting the supply voltage of the second amplifier with the regulated signal. 3. The method of claim 1, wherein the first amplifier is an S-class modulator having. 4. The method of claim 1, wherein the second amplifier is a B-class amplifier ker has.   5. The method of claim 1, wherein the combining step comprises the steps of:
Low-pass filtering the amplified low-frequency component to generate a low-pass filtered signal,
High-pass filtering the amplified high-frequency component to generate a high-pass filtered signal,
Combine the low-pass filtered signal with the high-pass filtered signal. 6. The method of claim 1, wherein the step of amplifying the low frequency component comprises the steps of:
Generate a pulse width modulated signal with a duty cycle that is proportional to an amplitude of the low-frequency component, and
Low pass filtering the pulse width modulated signal to produce the amplified low frequency component. 7. Adaptive split band modulator, which comprises:
a first amplifier having an input coupled to an input of the adaptive split band modulator;
a second amplifier having an input coupled to the input of the adaptive split band modulator; and
a combining network for combining an output of the first amplifier and an output of the second amplifier,
characterized,
that a peak detector is provided having an input coupled to the input of the adaptive split band modulator; and
that the second amplifier has a power supply input that is coupled to the output of the peak detector. 8. The adaptive split band modulator according to claim 7, wherein the first amplifier ker has an S-class modulator 9. The adaptive split band modulator according to claim 7, wherein the second ver more powerfully has a B-class amplifier.   10. The adaptive split band modulator of claim 7, further comprising a span voltage regulator, which between the output of the peak detector and the Power supply input of the second amplifier is connected.